Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

All organisms respond to various forms of stress, including heat shock. The heat shock response has been universally conserved from bacteria to humans. In Escherichia coli the heat shock response is under the positive transcriptional control of the sigma 32 polypeptide and involves transient acceleration in the rate of synthesis of a few dozen genes. Three of the heat shock genes--dnaK, dnaJ, and grpE--are special because mutations in any one of these lead to constitutive levels of heat shock gene expression, implying that their products negatively autoregulate their own synthesis. The DnaK, DnaJ, and GrpE proteins have been known to function in various biological situations, including bacteriophage lambda replication. Here, we report the formation of an ATP hydrolysis-dependent complex of DnaJ, sigma 32, and DnaK proteins in vitro. This DnaJ-sigma 32-DnaK complex has been seen under different conditions, including glycerol gradient sedimentation and co-immunoprecipitation. The DnaK and DnaJ proteins in the presence of ATP can interfere with the efficient binding of sigma 32 to the RNA polymerase core, and are capable of disrupting a preexisting sigma 32-RNA polymerase complex. Our results suggest a possible mechanism for the autoregulation of the heat shock response.
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PMID:Autoregulation of the Escherichia coli heat shock response by the DnaK and DnaJ heat shock proteins. 824 5

Most organisms respond to heat by substantial alteration of the pattern of gene expression. This has been particularly well studied with Escherichia coli although the response has by no means been completely characterized. Here we report the characterization of 26 new heat shock genes of E. coli, termed hsl, discovered by global transcription analysis with an overlapping lambda clone bank. We have measured the molecular weights of the corresponding heat shock proteins and mapped each of them to within a few kilobases on the E. coli genome. In vitro, 16 of them can be activated by the E sigma 32 RNA polymerase, which specifically transcribes heat shock genes. In vivo expression kinetics of seven of eight examined new proteins were found to be similar to those of the four most studied heat shock proteins, DnaK, DnaJ, GroEL (MopA), and GroES (MopB). In the course of this work, we confirmed that the catalytic subunit of the ATP-dependent Clp protease (also known as Ti protease), ClpP, is derived from a larger precursor protein. Possible assignments of some of the hsl genes to known proteins are discussed.
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PMID:Characterization of twenty-six new heat shock genes of Escherichia coli. 834 64

The chaperone system formed by DnaK, DnaJ and GrpE mediates stress-dependent negative modulation of the Escherichia coli heat shock response, probably through association with the heat shock promoter-specific sigma32 subunit of RNA polymerase. Interactions of the DnaK system with sigma32 were analysed. DnaJ and DnaK bind free, but not RNA polymerase-bound, sigma32 with dissociation constants of 20 nM and 5 muM respectively. Association and dissociation rates of DnaJ-sigma32 complexes are 5900- and 20-fold higher respectively than those of DnaK-sigma32 complexes in the absence of ATP. ATP destabilizes DnaK-sigma32 interactions. DnaJ, through rapid association with sigma32 and stimulation of hydrolysis of DnaK-bound ATP, mediates efficient binding of DnaK to sigma32 in the presence of ATP, resulting in DnaK-DnaJ-sigma32 complexes containing ADP. GrpE binding to these complexes stimulates nucleotide release and subsequent complex dissociation by ATP. We propose that the principles of this cycle also operate in other chaperone activities of the DnaK system. DnaK and DnaJ cooperatively inhibit sigma32 activity in heat shock gene transcription and GrpE partially reverses this inhibition. These data indicate that reversible inhibition of sigma32 activity through transient association of DnaK and DnaJ is a central regulatory element of the heat shock response.
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PMID:A cycle of binding and release of the DnaK, DnaJ and GrpE chaperones regulates activity of the Escherichia coli heat shock transcription factor sigma32. 859 44

The E. coli heat shock response is regulated at the transcriptional level through stress-dependent controls of the heat shock promoter-specific sigma32 subunit of RNA polymerase. A key aspect of this regulation, the sensing of stress and transmission of this information to sigma32, involves the chaperone system formed by the DnaK, DnaJ and GrpE heat shock proteins. This system mediates stress- dependent controls of levels and activity of sigma32 which rely, at least in part, on direct association of DnaK and DnaJ with sigma32. We identified DnaK binding sites within the sigma32 sequence by probing a cellulose-bound peptide library scanning sigma32. Two sites with high affinity for DnaK, containing the motifs RKLFFNLR and LRNWRIVK, were located centrally and peripherally, respectively, to the region C of sigma32, previously implicated genetically in chaperone-dependent control of sigma32 levels. Cloning and sequencing of rpoH homologs from five Gram-negative proteobacteria revealed that region C, including the DnaK binding motif central to it, is highly conserved among sigma32 homologs but missing in the other sigma factors. We propose that binding of DnaK to region C is central to a conserved regulatory mechanism allowing the sensing of stress by the heat shock gene transcription machinery.
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PMID:Regulatory region C of the E. coli heat shock transcription factor, sigma32, constitutes a DnaK binding site and is conserved among eubacteria. 860 34

High temperature and other environmental stresses induce the expression of several heat shock proteins in Caulobacter crescentus, including the molecular chaperones DnaJ, DnaK, GrpE, and GroEL and the Lon protease. We report here the isolation of the rpoH gene encoding a homolog of the Escherichia coli RNA polymerase sigma32 subunit, the sigma factor responsible for the transcription of heat shock promoters. The C. crescentus sigma32 homolog, predicted to be a 33.7-kDa protein, is 42% identical to E. coli sigma32 and cross-reacts with a monoclonal antibody to E. coli sigma32. Functional homology was demonstrated by complementing the temperature-sensitive growth defect of an E. coli rpoH deletion mutant with the C. crescentus rpoH gene. Immunoblot analysis showed a transient rise in sigma32 levels after a temperature shift from 30 to 42 degrees C similar to that described for E. coli. In addition, increasing the cellular content of sigma32 by introducing a plasmid-encoded copy of rpoH induced DnaK expression in C. crescentus cultures grown at 30 degrees C. The C. crescentus rpoH gene was transcribed from either of two heat shock consensus promoters. rpoH transcription and sigma32 levels increased coordinately following heat shock, indicating that transcriptional regulation contributes to sigma32 expression in this organism. Both the rpoH gene and sigma32 protein were expressed constitutively throughout the cell cycle at 30 degrees C. The isolation of rpoH provides an important tool for future studies of the role of sigma32 in the normal physiology of C. crescentus.
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PMID:Regulation of a heat shock sigma32 homolog in Caulobacter crescentus. 860 66

The complete 1,751,377-bp sequence of the genome of the thermophilic archaeon Methanobacterium thermoautotrophicum deltaH has been determined by a whole-genome shotgun sequencing approach. A total of 1,855 open reading frames (ORFs) have been identified that appear to encode polypeptides, 844 (46%) of which have been assigned putative functions based on their similarities to database sequences with assigned functions. A total of 514 (28%) of the ORF-encoded polypeptides are related to sequences with unknown functions, and 496 (27%) have little or no homology to sequences in public databases. Comparisons with Eucarya-, Bacteria-, and Archaea-specific databases reveal that 1,013 of the putative gene products (54%) are most similar to polypeptide sequences described previously for other organisms in the domain Archaea. Comparisons with the Methanococcus jannaschii genome data underline the extensive divergence that has occurred between these two methanogens; only 352 (19%) of M. thermoautotrophicum ORFs encode sequences that are >50% identical to M. jannaschii polypeptides, and there is little conservation in the relative locations of orthologous genes. When the M. thermoautotrophicum ORFs are compared to sequences from only the eucaryal and bacterial domains, 786 (42%) are more similar to bacterial sequences and 241 (13%) are more similar to eucaryal sequences. The bacterial domain-like gene products include the majority of those predicted to be involved in cofactor and small molecule biosyntheses, intermediary metabolism, transport, nitrogen fixation, regulatory functions, and interactions with the environment. Most proteins predicted to be involved in DNA metabolism, transcription, and translation are more similar to eucaryal sequences. Gene structure and organization have features that are typical of the Bacteria, including genes that encode polypeptides closely related to eucaryal proteins. There are 24 polypeptides that could form two-component sensor kinase-response regulator systems and homologs of the bacterial Hsp70-response proteins DnaK and DnaJ, which are notably absent in M. jannaschii. DNA replication initiation and chromosome packaging in M. thermoautotrophicum are predicted to have eucaryal features, based on the presence of two Cdc6 homologs and three histones; however, the presence of an ftsZ gene indicates a bacterial type of cell division initiation. The DNA polymerases include an X-family repair type and an unusual archaeal B type formed by two separate polypeptides. The DNA-dependent RNA polymerase (RNAP) subunits A', A", B', B" and H are encoded in a typical archaeal RNAP operon, although a second A' subunit-encoding gene is present at a remote location. There are two rRNA operons, and 39 tRNA genes are dispersed around the genome, although most of these occur in clusters. Three of the tRNA genes have introns, including the tRNAPro (GGG) gene, which contains a second intron at an unprecedented location. There is no selenocysteinyl-tRNA gene nor evidence for classically organized IS elements, prophages, or plasmids. The genome contains one intein and two extended repeats (3.6 and 8.6 kb) that are members of a family with 18 representatives in the M. jannaschii genome.
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PMID:Complete genome sequence of Methanobacterium thermoautotrophicum deltaH: functional analysis and comparative genomics. 937 63

The expression of heat shock genes in Escherichia coli is regulated by the antagonistic action of the transcriptional activator, the sigma32 subunit of RNA polymerase, and negative modulators. Modulators are the DnaK chaperone system, which inactivates and destabilizes sigma32, and the FtsH protease, which is largely responsible for sigma32 degradation. A yet unproven hypothesis is that the degree of sequestration of the modulators through binding to misfolded proteins determines the level of heat shock gene transcription. This hypothesis was tested by altering the modulator concentration in cells expressing dnaK, dnaJ and ftsH from IPTG and arabinose-controlled promoters. Small increases in levels of DnaK and the DnaJ co-chaperone (< 1.5-fold of wild type) resulted in decreased level and activity of sigma32 at intermediate temperature and faster shut-off of the heat shock response. Small decreases in their levels caused inverse effects and, furthermore, reduced the refolding efficiency of heat-denatured protein and growth at heat shock temperatures. Fewer than 1500 molecules of a substrate of the DnaK system, structurally unstable firefly luciferase, resulted in elevated levels of heat shock proteins and a prolonged shut-off phase of the heat shock response. In contrast, a decrease in FtsH levels increased the sigma32 levels, but the accumulated sigma32 was inactive, indicating that sequestration of FtsH alone cannot induce the heat shock response efficiently. DnaK and DnaJ thus constitute the primary stress-sensing and transducing system of the E. coli heat shock response, which detects protein misfolding with high sensitivity.
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PMID:Levels of DnaK and DnaJ provide tight control of heat shock gene expression and protein repair in Escherichia coli. 982 22

The Escherichia coli sigma 32 transcriptional regulator has been shown to be degraded both in vivo and in vitro by the FtsH (HflB) protease, a member of the AAA protein family. In our attempts to study this process in detail, we found that two sigma 32 mutants lacking 15-20 C-terminal amino acids had substantially increased half-lives in vivo or in vitro, compared with wild-type sigma 32. A truncated version of sigma 32, sigma 32 C delta, was purified to homogeneity and shown to be resistant to FtsH-dependent degradation in vitro, suggesting that FtsH initiates sigma 32 degradation from its extreme C-terminal region. Purified sigma 32 C delta interacted with the DnaK and DnaJ chaperone proteins in a fashion similar to that of wild-type sigma 32. However, in contrast to wild-type sigma 32, sigma 32 C delta was largely deficient in its in vivo and in vitro interaction with core RNA polymerase. As a consequence, the truncated sigma 32 protein was completely non-functional in vivo, even when overproduced. Furthermore, it is shown that wild-type sigma 32 is protected from degradation by FtsH when complexed to the RNA polymerase core, but sensitive to proteolysis when in complex with the DnaK chaperone machine. Our results are in agreement with the proposal that the capacity of the DnaK chaperone machine to autoregulate its own synthesis negatively is simply the result of its ability to sequester sigma 32 from RNA polymerase, thus making it accessible to degradation by the FtsH protease.
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PMID:On the mechanism of FtsH-dependent degradation of the sigma 32 transcriptional regulator of Escherichia coli and the role of the Dnak chaperone machine. 998 18

A large variety of stress conditions including physicochemical factors induce the synthesis of more than 20 heat shock proteins (HSPs). In E. coli, the heat shock response to temperature upshift from 30 to 42 degrees C consists of the rapid induction of these HSPs, followed by an adaptation period where the rate of HSP synthesis decreases to reach a new steady-state level. Major HSPs are molecular chaperones, including DnaK, DnaJ and GrpE, and GroEL and GroES, and proteases. They constitute the two major chaperone systems of E. coli (15-20% of total protein at 46 degrees C). They are important for cell survival, since they play a role in preventing aggregation and refolding proteins. The E. coli heat shock response is positively controlled at the transcriptional level by the product of the rpoH gene, the heat shock promoter-specific sigma32 subunit of RNA polymerase. Because of its rapid turn-over, the cellular concentration of sigma32 is very low under steady-state conditions (10-30 copies/cell at 30 degrees C) and is limiting for heat shock gene transcription. The heat shock response is induced as a consequence of a rapid increase in sigma32 levels and stimulation of sigma32 activity. The shut off of the response occurs as a consequence of declining sigma32 levels and inhibition of sigma32 activity. Stress-dependent changes in heat shock gene expression are mediated by the antagonistic action of sigma32 and negative modulators which act upon sigma32. These modulators are the DnaK chaperone system which inactivate sigma32 by direct association and mediate its degradation by proteases. Degradation of sigma32 is mediated mainly by FtsH (HflB), an ATP-dependent metallo-protease associated with the inner membrane. There is increasing evidence that the sequestration of the DnaK chaperone system through binding to misfolded proteins is a direct determinant of the modulation of the heat shock genes expression. A central open question is the identity of the binding sites within sigma32 for DnaK, DnaJ, FtsH and the RNA polymerase, and the functional interplay between these sites. We have studied the role of two distinct regions of sigma32 in its activity and stability control: region C and the C-terminal part. Both regions are involved in RNA polymerase binding.
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PMID:The heat shock response of Escherichia coli. 1082 72

Under non-stressed conditions in Escherichia coli, the heat shock transcription factor sigma(32) is rapidly degraded by the AAA protease FtsH. The DnaK chaperone system is also required for the rapid turnover of sigma(32) in the cell. It has been hypothesized that the DnaK chaperone system facilitates the degradation of sigma(32) by sequestering it from RNA polymerase core. This hypothesis predicts that mutant sigma(32) proteins, which are deficient in binding to RNA polymerase core, will be degraded independently of the DnaK chaperone system. We examined the in vivo stability of such mutant sigma(32) proteins. Results indicated that the mutant sigma(32) proteins as similar as authentic sigma(32) were stabilized in DeltadnaK and DeltadnaJ/DeltacbpA cells. The interaction between sigma(32) and DnaK/DnaJ/GrpE was not affected by these mutations. These results strongly suggest that the degradation of sigma(32) requires an unidentified active role of the DnaK chaperone system.
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PMID:Evidence for an active role of the DnaK chaperone system in the degradation of sigma(32). 1093 May 81


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